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Related Concept Videos

Properties of DTFT I01:24

Properties of DTFT I

In signal processing, Discrete-Time Fourier Transforms (DTFTs) play a critical role in analyzing discrete-time signals in the frequency domain. Various properties of the DTFTs such as linearity, time-shifting, frequency-shifting, time reversal, conjugation, and time scaling help understand and manipulate these signals for different applications.
The linearity property of DTFTs is fundamental. If two discrete-time signals are multiplied by constants a and b respectively, and then combined to...
Properties of DTFT II01:24

Properties of DTFT II

In the study of discrete-time signal processing, understanding the properties of the Discrete-Time Fourier Transform (DTFT) is crucial for analyzing and manipulating signals in the frequency domain. Several properties, including frequency differentiation, convolution, accumulation, and Parseval's relation, offer powerful tools for signal analysis.
The frequency differentiation property is illustrated by considering a DTFT pair and differentiating both sides with respect to ω. Multiplying by j...
Discrete Fourier Transform01:15

Discrete Fourier Transform

The Discrete Fourier Transform (DFT) is a fundamental tool in signal processing, extending the discrete-time Fourier transform by evaluating discrete signals at uniformly spaced frequency intervals. This transformation converts a finite sequence of time-domain samples into frequency components, each representing complex sinusoids ordered by frequency. The DFT translates these sequences into the frequency domain, effectively indicating the magnitude and phase of each frequency component present...
Discrete-time Fourier transform01:26

Discrete-time Fourier transform

The Discrete-Time Fourier Transform (DTFT) is an essential mathematical tool for analyzing discrete-time signals, converting them from the time domain to the frequency domain. This transformation allows for examining the frequency components of discrete signals, providing insights into their spectral characteristics. In the DTFT, the continuous integral used in the continuous-time Fourier transform is replaced by a summation to accommodate the discrete nature of the signal.
One of the notable...
Fast Fourier Transform01:10

Fast Fourier Transform

The Fast Fourier Transform (FFT) is a computational algorithm designed to compute the Discrete Fourier Transform (DFT) efficiently. By breaking down the calculations into smaller, manageable sections, the FFT significantly reduces the computational complexity involved. Direct computation of an N-point DFT requires N2 complex multiplications, whereas the FFT algorithm needs only (N/2)log⁡2N multiplications, offering a much faster performance.
The computational efficiency of the FFT becomes...
Discrete-Time Fourier Series01:20

Discrete-Time Fourier Series

The Discrete-Time Fourier Series (DTFS) is a fundamental concept in signal processing, serving as the discrete-time counterpart to the continuous-time Fourier series. It allows for the representation and analysis of discrete-time periodic signals in terms of their frequency components. Unlike its continuous counterpart, which utilizes integrals, the calculation of DTFS expansion coefficients involves summations due to the discrete nature of the signal.
For a discrete-time periodic signal x[n]...

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Fast delta Hadamard transform.

E E Fenimore, G S Weston

    Applied Optics
    |March 25, 2010
    PubMed
    Summary
    This summary is machine-generated.

    New fast delta Hadamard transforms (FDHT) improve measurement decoding for applications like spectroscopy and imaging. These methods overcome resolution limitations and phasing errors associated with the traditional fast Hadamard transform (FHT).

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    Area of Science:

    • * Signal processing and computational imaging.
    • * Optics and spectroscopy.
    • * Image reconstruction and analysis.

    Background:

    • * Multiplexing using m-sequences enhances measurement throughput in fields like spectroscopy and coded aperture imaging.
    • * Traditional decoding methods rely on the fast Hadamard transform (FHT), which offers computational efficiency but limits sampling resolution and can introduce phasing errors.
    • * Existing limitations hinder fine sampling and accurate reconstruction near sample boundaries.

    Purpose of the Study:

    • * To introduce novel 1-D and 2-D fast delta Hadamard transforms (FDHT) that overcome the limitations of the FHT.
    • * To enhance measurement decoding accuracy and resolution in multiplexed systems.
    • * To provide a unified mathematical framework for techniques in Hadamard spectroscopy and coded aperture imaging.

    Main Methods:

    • * Development of 1-D and 2-D fast delta Hadamard transforms (FDHT).
    • * Application of FDHT to decoding m-sequence encoded measurements.
    • * Integration of techniques from Hadamard spectroscopy and coded aperture imaging under the FDHT framework.

    Main Results:

    • * FDHT successfully overcomes the resolution sampling limitations inherent in the FHT.
    • * Phasing errors near sample boundaries are mitigated by the FDHT.
    • * The developed methods provide a unified mathematical basis for diverse imaging and spectroscopic techniques.

    Conclusions:

    • * The fast delta Hadamard transform (FDHT) offers a significant advancement in decoding multiplexed measurements.
    • * FDHT enhances spectral and image resolution and reduces artifacts compared to FHT.
    • * This work unifies disparate techniques in spectroscopy and imaging, paving the way for broader applications.